Title :
Normal-Conducting Separation and Compensation Dipoles for the LHC Experimental Insertions
Author :
Gurov, D. ; Kiselev, O. ; Morozov, I. ; Ogurtsov, A. ; Petrov, V. ; Ruvinsky, E. ; Sukhanov, A. ; Zhilayev, K. ; Bidon, S. ; Cornuet, D. ; Gérard, D. ; Hans, O. ; Kalbreier, W. ; Ramberger, S. ; de Rijk, G.
Author_Institution :
Budker Inst. of Nucl. Phys., Novosibirsk
fDate :
6/1/2006 12:00:00 AM
Abstract :
The experimental insertions of the LHC make use of normal-conducting magnets to provide for part of the beam separation and to compensate the effect of two large spectrometer dipoles. Three different types with respect to the length were designed and are based on the same type of lamination. The main type of magnet MBXW has a core length of 3.4 m while the MBXWT and MBXWS magnets are 1.5 m and 0.75 m long versions respectively. The magnet design was done in collaboration between CERN and BINP and the dipole magnets are produced by BINP. So far all three MBXWS magnets, all three MBXWT magnets and fifteen of twenty-nine MBXW magnets have been manufactured and delivered to CERN. The report presents the main design issues and results of the acceptance tests including mechanical, electrical and magnetic field measurements
Keywords :
accelerator magnets; electric field measurement; magnetic field measurement; mechanical variables measurement; particle spectrometers; proton accelerators; storage rings; synchrotrons; 0.75 m; 1.5 m; 3.4 m; BINP; CERN; LHC; MBXW magnet; MBXWS magnet; accelerator magnets; beam separation; compensation dipoles; dipole magnets; electrical field measurement; magnet design; magnetic field measurement; mechanical field measurement; normal-conducting magnets; spectrometer dipoles; Collaboration; Lamination; Large Hadron Collider; Magnetic cores; Magnetic field measurement; Magnetic fields; Magnets; Manufacturing; Spectroscopy; Testing; Accelerator magnets; LHC; normal-conducting magnets;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.869553
